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*DECK MACINI
SUBROUTINE MACINI(NENTRY,HENTRY,IENTRY,JENTRY,KENTRY)
*
*-----------------------------------------------------------------------
*
*Purpose:
* Construct a new macrolib that will contain one mixture number per
* material region; fuel-map macrolib is required.
*
*Copyright:
* Copyright (C) 2007 Ecole Polytechnique de Montreal.
*
*Author(s):
* J. Koclas, E. Varin, D. Sekki
*
*Parameters: input
* NENTRY number of data structures transfered to this module.
* HENTRY name of the data structures.
* IENTRY data structure type where:
* IENTRY=1 for LCM memory object;
* IENTRY=2 for XSM file;
* IENTRY=3 for sequential binary file;
* IENTRY=4 for sequential ASCII file.
* JENTRY access permission for the data structure where:
* JENTRY=0 for a data structure in creation mode;
* JENTRY=1 for a data structure in modifications mode;
* JENTRY=2 for a data structure in read-only mode.
* KENTRY data structure pointer.
*
*Comments:
* The MACINI: module specification is:
* MACRO2 MATEX := MACINI: MATEX MACRO [ MACFL ] :: [ EDIT iprint ] [ FUEL ] ;
* where
* MACRO2 : name of the extended \emph{macrolib} to be created by the module.
* MATEX : name of the \emph{matex} object containing an extended material
* index over the reactor geometry. MATEX must be specified in the
* modification mode; it will store the recovered h-factors per each fuel
* region.
* MACRO : name of a \emph{macrolib}, created using either MAC:, CRE:, NCR:
* or AFM: module, for the evolution-independent material properties
* (see structure (desccre1) or refer to the DRAGON user guide).
* MACFL : name of a fuel-map \emph{macrolib}, created using either CRE:,
* NCR: or AFM: module, for the interpolated fuel properties (see structure
* (desccre2) or refer to the DRAGON user guide).
* EDIT : keyword used to set iprint.
* iprint : integer index used to control the printing on screen: = 0 for
* no print; = 1 for minimum printing; larger values produce increasing
* amounts of output. The default value is iprint = 1.
* FUEL : keyword used to indicate that MACRO is a fuel-map \emph{macrolib}
* in case where only two RHS objects are defined. By default, MACRO contains
* evolution-independent cross sections.
*
*-----------------------------------------------------------------------
*
USE GANLIB
*----
* SUBROUTINE ARGUMENTS
*----
INTEGER NENTRY,IENTRY(NENTRY),JENTRY(NENTRY)
TYPE(C_PTR) KENTRY(NENTRY)
CHARACTER HENTRY(NENTRY)*12
*----
* LOCAL VARIABLES
*----
PARAMETER(NSTATE=40,IOUT=6)
CHARACTER HSIGN*12,TEXT*12
INTEGER ISTATE(NSTATE)
DOUBLE PRECISION DFLOT
LOGICAL LMAP,LWD1,LWD2
TYPE(C_PTR) IPMAC,IPMTX,IPMAC1,IPMAC2,JPMAC,KPMAC
INTEGER, ALLOCATABLE, DIMENSION(:) :: MIX
REAL, ALLOCATABLE, DIMENSION(:) :: HFAC,WDLA
*----
* PARAMETER VALIDATION
*----
IF((NENTRY.LE.2).OR.(NENTRY.GE.5))
1 CALL XABORT('@MACINI: 3 OR 4 PARAMETERS EXPECTED.')
IF((IENTRY(1).NE.1).AND.(IENTRY(1).NE.2))CALL XABORT('@MACINI:'
1 //' LCM OBJECT EXPECTED AT LHS.')
IF(JENTRY(1).NE.0)CALL XABORT('@MACINI: CREATE MODE EXPECTED'
1 //' FOR L_MACROLIB AT LHS.')
IPMAC=KENTRY(1)
* L_MATEX
IF((IENTRY(2).NE.1).AND.(IENTRY(2).NE.2))CALL XABORT('@MACINI:'
1 //' LCM OBJECT EXPECTED AT RHS.')
IF(JENTRY(2).NE.1)CALL XABORT('@MACINI: MODIFICATION MODE EX'
1 //'PECTED FOR L_MATEX OBJECT.')
CALL LCMGTC(KENTRY(2),'SIGNATURE',12,HSIGN)
IF(HSIGN.NE.'L_MATEX')THEN
TEXT=HENTRY(2)
CALL XABORT('@MACINI: SIGNATURE OF '//TEXT//' IS '//HSIGN//
1 '. L_MATEX EXPECTED AT RHS.')
ENDIF
IPMTX=KENTRY(2)
DO IEN=3,NENTRY
IF((IENTRY(IEN).NE.1).AND.(IENTRY(IEN).NE.2))CALL XABORT('@MACIN'
1 //'I: LCM OBJECT EXPECTED AT RHS.')
IF(JENTRY(IEN).NE.2)CALL XABORT('@MACINI: READ-ONLY MODE EXPEC'
1 //'TED FOR THE LCM OBJECTS AT RHS.')
ENDDO
* L_MACROLIB(1)
CALL LCMGTC(KENTRY(3),'SIGNATURE',12,HSIGN)
IF(HSIGN.NE.'L_MACROLIB')THEN
TEXT=HENTRY(3)
CALL XABORT('@MACINI: SIGNATURE OF '//TEXT//' IS '//HSIGN//
1 '. FIRST MACROLIB EXPECTED AT RHS.')
ENDIF
IPMAC1=KENTRY(3)
* L_MACROLIB(2)
IF(NENTRY.EQ.4) THEN
CALL LCMGTC(KENTRY(4),'SIGNATURE',12,HSIGN)
IF(HSIGN.NE.'L_MACROLIB')THEN
TEXT=HENTRY(4)
CALL XABORT('@MACINI: SIGNATURE OF '//TEXT//' IS '//HSIGN//
1 '. FUEL-MAP MACROLIB EXPECTED AT RHS.')
ENDIF
IPMAC2=KENTRY(4)
ELSE
IPMAC2=C_NULL_PTR
ENDIF
*----
* RECOVER INFORMATION
*----
ISTATE(:NSTATE)=0
CALL LCMGET(IPMAC1,'STATE-VECTOR',ISTATE)
* MACROLIB(1)-INFO
NGRP=ISTATE(1)
NMIX1=ISTATE(2)
NL=ISTATE(3)
NF1=ISTATE(4)
NDEL1=ISTATE(7)
NDEL2=0
LEAK=ISTATE(9)
NW1=ISTATE(10)
* MACROLIB(2)-INFO
NF2=1
IF(NENTRY.EQ.4) THEN
ISTATE(:NSTATE)=0
CALL LCMGET(IPMAC2,'STATE-VECTOR',ISTATE)
NMIX2=ISTATE(2)
NDEL2=ISTATE(7)
NL=MAX(ISTATE(3),NL)
NW2=ISTATE(10)
NF2=ISTATE(4)
IF((NF2.NE.NF1).AND.(NF1.GT.1)) THEN
WRITE(IOUT,*)'MACROLIB=',HENTRY(1),' NF=',NF1,' (0 EXPECTED)'
WRITE(IOUT,*)'MACROLIB=',HENTRY(2),' NF=',NF2
CALL XABORT('@MACINI: INCONSISTENT NUMBER OF FISSILE ISOTOPE'
1 //'S.')
ENDIF
IF(ISTATE(1).NE.NGRP)CALL XABORT('@MACINI: DIFFERENT NGRP'
1 //' NUMBER IN TWO MACROLIB OBJECTS.')
IF(ISTATE(3).NE.NL)CALL XABORT('@MACINI: INCONSISTENT NL '
1 //'NUMBER IN TWO MACROLIB OBJECTS.')
IF(ISTATE(9).NE.LEAK)CALL XABORT('@MACINI: DIFFERENT LEAK'
1 //' NUMBER IN TWO MACROLIB OBJECTS.')
ENDIF
ISTATE(:NSTATE)=0
CALL LCMGET(IPMTX,'STATE-VECTOR',ISTATE)
* MATEX-INFO
NMIX=ISTATE(2)
NTOT=ISTATE(5)
ALLOCATE(MIX(NTOT))
MIX(:NTOT)=0
CALL LCMGET(IPMTX,'MAT',MIX)
IMPX=1
LMAP=.FALSE.
10 CALL REDGET(ITYP,NITMA,FLOT,TEXT,DFLOT)
IF(ITYP.EQ.10)GOTO 20
IF(ITYP.NE.3)CALL XABORT('@MACINI: CHARACTER DATA EXPECTED.')
IF(TEXT.EQ.'EDIT')THEN
* READ PRINTING INDEX
CALL REDGET(ITYP,IMPX,FLOT,TEXT,DFLOT)
IF(ITYP.NE.1)CALL XABORT('@MACINI: INTEGER FOR EDIT EXPECTED.')
ELSE IF(TEXT.EQ.'FUEL')THEN
* ASSUME FUEL-MAP MACROLIB
IF(NENTRY.NE.3) CALL XABORT ('@MACINI: 3 PARAMETERS EXPECTED.')
LMAP=.TRUE.
ELSE IF(TEXT.EQ.';')THEN
GO TO 20
ELSE
CALL XABORT('@MACINI: FINAL ; EXPECTED.')
ENDIF
GO TO 10
*----
* NEW MACROLIB CREATION
*----
20 IF(IMPX.GT.1)WRITE(IOUT,*)'NUMBER OF ENERGY GROUPS ',NGRP
IF(IMPX.GT.1)WRITE(IOUT,*)'TOTAL NUMBER OF MIXTURES ',NMIX
* DO NOT INCLUDE FUEL PROPERTIES
IF(IMPX.GT.0)WRITE(IOUT,*)'** TREATING FIRST MACROLIB **'
CALL MACCRE(IPMAC1,IPMAC,NL,NW1,NF1,NGRP,NMIX1,NMIX,NTOT,MIX,LMAP,
1 IMPX)
IF(IMPX.GT.1)CALL LCMLIB(IPMAC)
* INCLUDE FUEL PROPERTIES
IF(NENTRY.EQ.4) THEN
LMAP=.TRUE.
IF(IMPX.GT.0)WRITE(IOUT,*)'** TREATING FUEL-MAP MACROLIB **'
CALL MACCRE(IPMAC2,IPMAC,NL,NW2,NF2,NGRP,NMIX2,NMIX,NTOT,MIX,
1 LMAP,IMPX)
ENDIF
DEALLOCATE(MIX)
*----
* RECOVER LAMBDA-D
*----
CALL LCMLEN(IPMAC1,'LAMBDA-D',LENGTH,ITYLCM)
LWD1=(LENGTH.EQ.NDEL1).AND.(NDEL1.GT.0)
LWD2=.FALSE.
IF(NENTRY.EQ.4) THEN
CALL LCMLEN(IPMAC2,'LAMBDA-D',LENGTH,ITYLCM)
LWD2=(LENGTH.EQ.NDEL2).AND.(NDEL2.GT.0)
ENDIF
NDEL=0
IF(LWD1) THEN
NDEL=NDEL1
ALLOCATE(WDLA(NDEL))
CALL LCMGET(IPMAC1,'LAMBDA-D',WDLA)
CALL LCMPUT(IPMAC,'LAMBDA-D',NDEL,2,WDLA)
DEALLOCATE(WDLA)
ELSE IF(LWD2) THEN
NDEL=NDEL2
ALLOCATE(WDLA(NDEL))
CALL LCMGET(IPMAC2,'LAMBDA-D',WDLA)
CALL LCMPUT(IPMAC,'LAMBDA-D',NDEL,2,WDLA)
DEALLOCATE(WDLA)
ENDIF
*----
* STATE-VECTOR
*----
ISTATE(:NSTATE)=0
ISTATE(1)=NGRP
ISTATE(2)=NMIX
ISTATE(3)=NL
IF(NENTRY.EQ.3) THEN
ISTATE(4)=NF1
ELSE IF(NENTRY.EQ.4) THEN
ISTATE(4)=NF2
ENDIF
ISTATE(7)=NDEL
ISTATE(9)=LEAK
CALL LCMPUT(IPMAC,'STATE-VECTOR',NSTATE,1,ISTATE)
HSIGN='L_MACROLIB'
CALL LCMPTC(IPMAC,'SIGNATURE',12,HSIGN)
IF(IMPX.GT.0)CALL LCMLIB(IPMAC)
*----
* RECOVER H-FACTOR AND SAVE ON L_MATEX
*----
ALLOCATE(HFAC(NMIX*NGRP))
JPMAC=LCMGID(IPMAC,'GROUP')
DO JGR=1,NGRP
KPMAC=LCMGIL(JPMAC,JGR)
CALL LCMLEN(KPMAC,'H-FACTOR',LENGT,ITYP)
IF(LENGT.NE.NMIX)CALL XABORT('@MACINI: UNABLE TO FIND H'
1 //'-FACTOR BLOCK DATA IN THE NEW MACROLIB.')
CALL LCMGET(KPMAC,'H-FACTOR',HFAC((JGR-1)*NMIX+1))
ENDDO
CALL LCMPUT(IPMTX,'H-FACTOR',NMIX*NGRP,2,HFAC)
DEALLOCATE(HFAC)
RETURN
END
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